DE9308688U1 - Shuttering block - Google Patents

Abstract

A shuttering block exhibits two longitudinal walls, forming an outer wall (1) and an inner wall (2), at least two transverse walls (3), extending only over part of the height of the block, a cavity (8), located between the walls and intended for filling with concrete, and an insulating insert (6) arranged on the inner side of at least one of the two longitudinal walls. In relation to the lateral end sides of the block, the transverse walls (3) are offset inwards, as a result of which, in the known manner, the shuttering block is formed at least approximately in the form of an H. In each case one further insulating insert (7) is pushed over the transverse walls (3), said insert enclosing the transverse walls (3) in each case laterally and in the region of their reduced height. <IMAGE>

Description

PATENT ATTORNEY Pasanenstr. 7 DIPL.-ING. WERNER LORENZ 7920 Heidenheim

25.05.1993 yes/ks File: G 2812
Applicant:

Siegfried Gebhart

Tobelstadel

7971 Aichstetten-Aitrach

Formwork block

The invention relates to a formwork block with two longitudinal walls that form an outer wall and an inner wall, which are connected to one another by at least two transverse walls that extend only over part of the block height, with a cavity between the walls for filling with concrete, and with an insulation insert that is arranged on the inside of at least one of the two longitudinal walls.

In construction, especially in house building, formwork blocks are increasingly being used, especially for basements. They are usually made of concrete.

Formwork blocks can also be used very well for the entire walls of a house. Generally, only the first layer of blocks is set in mortar and the rest of the wall is built up dry, like a modular system, so that even non-construction professionals can build such structures.

The formwork blocks are therefore manufactured with relatively high precision and are usually provided with a tongue and groove for joining them together.

After the formwork blocks have been laid one above the other in a bond up to the floor, their cavities are filled with concrete. Using the simplest of methods, this results in a very stable wall, although it has very little thermal insulation.

For this reason, i.e. to improve thermal insulation, formwork blocks with insulation inserts have already been developed.

Such a formwork block is described in DE-OS 19 16 400.

It is made of lightweight concrete with an additive of foamed plastic particles and has an outer wall, inner wall, two end walls and a central connecting wall. The cavities formed by the stone connections are shielded on at least one side with panels made of heat-insulating material. Inwardly projecting noses or ribs can be used to hold these panels. The end walls and the connecting wall are provided with semicircular recesses on their upper and lower edges to allow the concrete to be poured in from one stone to the next in a horizontal direction.

Such a formwork block is also disclosed in DE 34 32 925. It consists of an outer wall, an inner wall and two end walls. This formwork block also uses an insulation insert to improve thermal insulation and sound insulation. This extends without interruption over the inside of the outer wall, the insides of the two end walls and along the recesses that are in the end walls and are used for filling the concrete. This formwork block already has good thermal insulation properties, but these can still be improved. The same applies to sound insulation.

The present invention is therefore based on the object of creating a formwork block of the type mentioned at the outset which is easy to handle, has very good thermal insulation properties and whose sound insulation properties are greatly improved.

According to the invention, this object is achieved in that/3 the transverse walls - in relation to the lateral front sides of the stone - are set inwards, whereby in a known manner the formwork stone forms at least approximately a �EEgr; shape, and that a further insulation insert is placed over the transverse walls, which surrounds the transverse walls laterally and in the area of their reduced height.

The formwork block designed in this way is very well insulated against heat and, above all, sound. The basis for this is the creation of the inward-set transverse walls instead of the usual end walls. This creates evenly sized channels or cavities that offer ideal opportunities for filling with concrete. Because the transverse walls only extend over part of the block height, the formwork blocks in a row are connected to one another by the concrete filling. A uniform spread of the concrete

This ensures that the pressure is maintained and that the formwork blocks are securely bonded together.

The improved thermal insulation of the formwork block according to the invention is achieved, among other things, by the inwardly placed transverse walls with the insulation insert placed over them or surrounding them. In the formwork block according to DE 34 32 925, the transverse walls arranged on the outside of the longitudinal walls of adjacent blocks abut directly against one another. This results in a very large uninsulated area, with a further disadvantage being that the abutting transverse walls can only be insulated inadequately by insulation.

In addition, the so-called "tiled stove effect" can be particularly effective because the heat in the interior is stored in the concrete.

A further advantage is that the tongue and groove on the front sides of the formwork blocks, which is common with other formwork blocks, can be dispensed with.

On the one hand, this makes the production of such a "smooth" stone much easier. On the other hand, it makes it much easier to adjust the length of the wall to the desired length, since if necessary, only the free ends, i.e. those of the "H" formed in the longitudinal walls, need to be shortened.

In a further embodiment of the invention, it can be provided that the outer wall is provided with the insulation insert and that the transverse walls on their underside are at least approximately flush with the underside of the stone, i.e. the underside of the longitudinal walls, with the further insulation insert being placed over each transverse wall from above.

This makes it easy to complete the formwork block with the additional insulation insert.

At the same time, the insulation insert placed over the two transverse walls and attached to the inside of the outer wall ensures that the heat cannot be transported to the outside. In addition, almost optimal sound insulation is achieved.

&mdash; "7 &mdash;

It is advantageous if the insulation insert for the longitudinal wall and the transverse walls are made in one piece. Both insulations can be installed in one step.

Furthermore, it can be provided that the thickness of the insulation inserts for the cross walls decreases towards the inner side of the stone facing the interior of the building on both sides of the cross walls.

This means a saving of material for the insulation inserts. In addition, the concentration of the material towards the outside is completely sufficient for heat and sound insulation.

Another advantage of this reduction in width towards the inside of the stone is that it creates more space for the concrete filling and thus allows a higher static load-bearing capacity of the masonry constructed with it. A step shape could also be used for this.

However, it is particularly advantageous if the insulation inserts for the transverse walls (seen from above) are facing the stone wall facing the interior of the building.

tapered towards the inside. This makes the manufacture of the insulation inserts easier.

It can be provided that the width reduction of the insulation inserts for the transverse walls in the area surrounding them from the outside to the inside is at least approximately 2:1.

A further advantageous embodiment of the formwork block according to the invention can consist in that with a formwork block length of approx. 500 mm, the maximum width of each insulation insert for a transverse wall is approx. 20 to 40 mm for the area projecting laterally beyond a transverse wall.

Furthermore, it can be provided that with a formwork block length of approximately 500 mm, the maximum width of each insulation insert for a transverse wall is at least approximately 30 mm for the area projecting laterally beyond a transverse wall.

These values have proven to be particularly advantageous in practice.

Furthermore, it can be provided that with a formwork block length of 500 mm, the transverse walls have a thickness

of approximately 50 mm each and a distance of 200 mm from each other, which always results in equal spaces for filling with concrete.

However, it may also be possible that/3 with a formwork block thickness of approx. 3 00 mm, the wall thicknesses of the longitudinal walls are approx. 45 to 55 mm and the insulation insert, which extends along a longitudinal wall, is approx. 50 to 60 mm.

In a further embodiment of the invention, it can also be provided that the area of each insulation insert covering the transverse walls on the upper side is approximately 10 to 30 mm.

In practice, it has proven to be even more advantageous if the area of each insulation insert covering the transverse walls on the top is approx. 15 mm.

All of these values have proven to be the most effective in practice. The formwork block designed in this way is therefore relatively low in material consumption and yet very stable. It is therefore easy to handle for installation work.

It can be made of expanded clay and

The concrete filling to be filled can be in the form of lightweight concrete.

A very advantageous development of the invention can consist in the insulation inserts for the longitudinal wall and the transverse walls being made of polystyrene. While the concrete that is filled shrinks after a certain time, the polystyrene material used for the insulation inserts offers the possibility of compensating for this shrinkage by initially being slightly pressed when the concrete is filled and then expanding back into its original shape after the concrete has shrunk. In this way, hollow spaces and thus sound and cold bridges are avoided.

A very advantageous embodiment of the invention can also consist in the fact that the transverse walls each have transition areas directed towards the top of the stone in the connection area with the longitudinal walls.

This improves the stability of the formwork block. The transition area can be in the form of a radius or, for easier production, in a simply bevelled shape.

The following drawing shows an execution

-11-example of the invention shown in principle.

It shows:

Fig. 1 is a plan view of the shuttering block according to the invention;

Fig. 2 a front view of the formwork block.

The formwork block has two longitudinal walls that form an outer wall 1 and an inner wall 2. Both longitudinal walls 1 and 2 are approximately 500 mm long, 250 mm high and have a wall thickness of approximately 45 to 55 mm. They are connected to each other at right angles by two transverse walls 3 (dashed representation).

In relation to the side faces (the face of the outer and inner walls 1 and 2), the transverse walls are each set approx. 100 mm inwards, so that the formwork block forms approximately the shape of an "H" and results in a total width of the formwork block of approx. 300 mm.

The transverse walls 3 are arranged at a distance of approx. 200 mm from each other based on the formwork block length of approx. 500 mm. This also results in

Laying the individual formwork blocks in a bond, i.e. offset by half a side length in each row, always with the same distance of approx. 2 00 mm.

Both transverse walls 3 are connected flush with the stone underside on their underside and extend to a stone height of approx. 170 mm.

In their connecting area, the cross walls 3 have approximately 80 mm high, bevelled transition areas 4 directed towards the top of the stone. Because the cross walls only reach up to the top of the stone in the transition areas, free spaces 5 are created which are useful for later filling with concrete horizontally in the longitudinal direction of the stone.

An insulation insert 6 is located on the inside of the outer wall 1. It has the same length and height as the outer wall and a wall thickness of approximately 50 to 60 mm. A further insulation insert 7, which surrounds each transverse wall 3 at the sides and in the area of its reduced height, is placed over each transverse wall 3 from above, flush with the underside of the insulation insert 6 and the underside of the formwork block.

Each insulation insert 7 covers the top of the transverse walls 3 by a height of approx. 15 mm. This dimension, which protrudes above the transverse walls 3, can also vary between approx. 10 and 30 mm.

The width of the insulation insert 7 decreases towards the inside of the stone facing the building, on both sides of the transverse walls.

From Fig. 1 it can be seen that this is achieved by tapering these insulation inserts 7 in a wedge shape in the direction described above. The ratio of this width reduction from outside to inside is approximately 2:1.

Each transverse wall 3 is also overhung by the insulation insert 7 on both sides of the transverse wall 3 in a range of 20 to 40 mm, but at least approximately 30 mm.

The walls 1, 2 and 3 as well as the insulation inserts 6 and 7 enclose a cavity 8 thus formed, which is connected to the free spaces 5 formed by adjacent formwork blocks. Through the evenly sized cavities 8 and the free spaces 5, after laying the formwork blocks in the bond from above

As is well known, the concrete is poured in. This also holds the insulation inserts 6 and 7 in their position and does not need to be separately attached to the formwork stone walls.

Claims (14)

PATENT ATTORNEY Fasanenstr. 7 DIPL.-ING. WERNER LORENZ 7920 Heidenheim 25.05.1993 Lo/ks File: G 2812 A Applicant: Siegfried Gebhart Tobelstadel Aichstetten-Aitrach -n&mdash;fe fern P - farn s &rgr; r ü c h e 1. Formwork block with two longitudinal walls forming an outer wall and an inner wall, which are connected to each other by at least two transverse walls which extend over only part of the block height, with a cavity between the walls for filling with concrete, and with an insulation insert which is arranged on the inside of at least one of the two longitudinal walls,
characterized by/3
the transverse walls (3) - relative to the lateral front sides of the stone - are set inwards, whereby the formwork stone forms at least approximately a &EEgr;-shape in a known manner, and da/3 -2- a further insulation insert (7) is placed over each of the transverse walls (3), which surrounds the transverse walls (3) on the sides and in the area of their reduced height. 2. Formwork block according to claim 1,
characterized by/3
the outer wall (1) is provided with the insulation insert (6), and the cross walls (3) are at least approximately flush with the underside of the stone on their underside, the further insulation insert (7) being placed over the cross walls (3) from above. 3. Formwork block according to claim 1 or 2,
characterized in that
the insulation inserts (6) for the longitudinal wall (1) and for the transverse walls (3) are one-piece. 4. Formwork block according to one of claims 1 to 3,
characterized by/3
the width of the insulation inserts (7) for the transverse walls (3) decreases towards the inner side of the stone facing the interior of the building on both sides of the transverse walls (3). -3- 5. Formwork block according to claim 4,
characterized by/?
the insulation inserts (7) for the transverse walls (3) taper in a wedge shape in the plan view towards the inner side of the stone facing the interior of the building. 6. Formwork block according to claim 4 and 5,
characterized by/3
the ratio of the width reduction of the insulation inserts (7) for the transverse walls (3) in the area surrounding them laterally from the outside to the inside is at least approximately 2:1. 7. Formwork block according to claim 6,
characterized in that
With a formwork block length of approx. 500 mm, the maximum width of each insulation insert (7) for a transverse wall (3) is approx. 20 to 40 mm for the area projecting laterally beyond a transverse wall (3). 8. Formwork block according to claim 7,
characterized in that
for a formwork block length of approx. 500 mm, the maximum width of each insulation insert (7) for -4- a transverse wall (3) is at least approximately 30 mm for the area laterally projecting beyond a transverse wall (3). 9. Formwork block according to claim 7 or 8, characterized by/3
With a formwork block length of approx. 500 mm, the transverse walls (3) each have a thickness of approx. 50 mm and a distance of approx. 200 mm from each other. 10. Formwork block according to one of claims 7, 8 or 9, characterized in that
With a formwork block thickness of approx. 300 mm, the wall thicknesses of the longitudinal walls (1,2) are approx. 45 to 55 mm and the insulation insert (6), which extends along a longitudinal wall, is approx. 50 to 60 mm. 11. Formwork block according to one of claims 2 to 10,
characterized in that
the area of each insulation insert (7) covering the transverse walls (3) on the top is approximately 10 to 30 mm. 12. Formwork block according to one of claims 2 to 10, -5- characterized in that the area of each insulation insert (7) covering the transverse walls (3) on the upper side is approximately 15 mm. 13. Formwork block according to one of claims 1 to 12, characterized in that the insulation inserts (6, 7) consist of polystyrene. 14. Formwork block according to one of claims 1 to 13, characterized in that the transverse walls (3) each have transition areas (4) directed towards the top of the block in the connection area with the longitudinal walls (1, 2).